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Helix major groove

Figure 8.9 The helix-turn-hellx motif in lambda Cro bound to DNA (orange) with the two recognition helices (red) of the Cro dimer sitting in the major groove of DNA. Figure 8.9 The helix-turn-hellx motif in lambda Cro bound to DNA (orange) with the two recognition helices (red) of the Cro dimer sitting in the major groove of DNA.
The protein dimer binds so that the recognition a helices at opposite ends of the protein molecule are in the major groove of the DNA as predicted, where they interact with base pairs at the end of the DNA molecule. Since these binding sites are separated by one turn of the DNA helix, it follows that at the center of the DNA molecule the narrow groove faces the protein... [Pg.138]

Structural studies of a repressor-DNA complex have shown that helices 4 and 5 form a helix-turn-helix motif and that side chains from the recognition helix 5 form water-mediated interactions with bases in the major groove. [Pg.142]

Figure 8.22 The lac repressor molecule is a V-shaped tetramer in which each arm is a dimer containing a DNA-hinding site. The helix-tum-helix motifs (red) of each dimer bind in two successive major grooves and the hinge helices (purple) bind adjacent to each other in the minor groove between the two major groove binding sites. The four subunits of the tetramer are held together by the four C-terminal helices (yellow) which form a four helix bundle. The bound DNA fragments are bent. (Adapted from M. Lewis et al., Science 271 1247-1254, 1996.)... Figure 8.22 The lac repressor molecule is a V-shaped tetramer in which each arm is a dimer containing a DNA-hinding site. The helix-tum-helix motifs (red) of each dimer bind in two successive major grooves and the hinge helices (purple) bind adjacent to each other in the minor groove between the two major groove binding sites. The four subunits of the tetramer are held together by the four C-terminal helices (yellow) which form a four helix bundle. The bound DNA fragments are bent. (Adapted from M. Lewis et al., Science 271 1247-1254, 1996.)...
Figure 8.23 The helix-turn-helix motifs of the subunits of both the PurR and the lac repressor subunits bind to the major groove of DNA with the N-terminus of the second helix, the recognition helix, pointing into the groove. The two hinge helices of each arm of the V-shaped tetramer bind adjacent to each other in the minor groove of DNA, which is wide and shallow due to distortion of the B-DNA structure. (Adapted from M.A. Schumacher et al.. Science 266 763-770, 1994.)... Figure 8.23 The helix-turn-helix motifs of the subunits of both the PurR and the lac repressor subunits bind to the major groove of DNA with the N-terminus of the second helix, the recognition helix, pointing into the groove. The two hinge helices of each arm of the V-shaped tetramer bind adjacent to each other in the minor groove of DNA, which is wide and shallow due to distortion of the B-DNA structure. (Adapted from M.A. Schumacher et al.. Science 266 763-770, 1994.)...
Some of the procaryotic DNA-binding proteins are activated by the binding of an allosteric effector molecule. This event changes the conformation of the dimeric protein, causing the helix-tum-helix motifs to move so that they are 34 A apart and able to bind to the major groove. The dimeric repressor for purine biosynthesis, PurR, induces a sharp bend in DNA upon binding caused by insertion of a helices in the minor groove between the two... [Pg.147]

Most sequence-specific regulatory proteins bind to their DNA targets by presenting an a helix or a pair of antiparallel p strands to the major groove of DNA. Recognition of the TATA box by TBP is therefore exceptional it utilizes a concave pleated sheet protein surface that interacts with the minor groove of DNA. Since the minor groove has very few sequence-specific... [Pg.156]

Figure 9.10 Schematic diagrams illustrating the complex between DNA (orange) and one monomer of the homeodomain. The recognition helix (red) binds in the major groove of DNA and provides the sequence-specific interactions with bases in the DNA. The N-terminus (green) binds in the minor groove on the opposite side of the DNA molecule and arginine side chains make nonspecific interactions with the phosphate groups of the DNA. (Adapted from C.R. Kissinger et al Cell 63 579-590, 1990.)... Figure 9.10 Schematic diagrams illustrating the complex between DNA (orange) and one monomer of the homeodomain. The recognition helix (red) binds in the major groove of DNA and provides the sequence-specific interactions with bases in the DNA. The N-terminus (green) binds in the minor groove on the opposite side of the DNA molecule and arginine side chains make nonspecific interactions with the phosphate groups of the DNA. (Adapted from C.R. Kissinger et al Cell 63 579-590, 1990.)...
Figure 9.14 The two domains of the POU region bind in tandem on opposite sides of the DNA double helix. Both the POU-specific domain and the POU homeodomain have a helix-turn-helix motif (blue and red) which binds to DNA with their recognition helices (red) in the major groove. The linker region that joins these domains is partly disordered. (Adapted from J.D. Klemm et al.. Cell 77 21-32, 1994.)... Figure 9.14 The two domains of the POU region bind in tandem on opposite sides of the DNA double helix. Both the POU-specific domain and the POU homeodomain have a helix-turn-helix motif (blue and red) which binds to DNA with their recognition helices (red) in the major groove. The linker region that joins these domains is partly disordered. (Adapted from J.D. Klemm et al.. Cell 77 21-32, 1994.)...
Figure 9.20 Diagram iliustrating the sequence-specific interactions between DNA and p53. The C-terminai a helix and loop LI of p53 bind in the major groove of the DNA. Arg 280 from the a helix and Lys 120 from LI form important specific interactions with bases of the DNA. In addition, Arg 248 from loop L3 binds to the DNA in the minor groove. (Adapted from Y. Cho et al.. Science 265 346-355, 1994.)... Figure 9.20 Diagram iliustrating the sequence-specific interactions between DNA and p53. The C-terminai a helix and loop LI of p53 bind in the major groove of the DNA. Arg 280 from the a helix and Lys 120 from LI form important specific interactions with bases of the DNA. In addition, Arg 248 from loop L3 binds to the DNA in the minor groove. (Adapted from Y. Cho et al.. Science 265 346-355, 1994.)...
Figure 10.3 Schematic diagram of the stmcture of three zinc fingers of Zif 268 bound to DNA. The three zinc fingers, which bind In tandem to the major groove of DNA, are colored blue, red and green from the N-terminus. The zinc fingers have the same stmcture and bind in a similar way with the N-terminus of the a helix pointing into the major groove. (Adapted from N.P. Pavletich et al.. Science 261 1701-1707, 1993.)... Figure 10.3 Schematic diagram of the stmcture of three zinc fingers of Zif 268 bound to DNA. The three zinc fingers, which bind In tandem to the major groove of DNA, are colored blue, red and green from the N-terminus. The zinc fingers have the same stmcture and bind in a similar way with the N-terminus of the a helix pointing into the major groove. (Adapted from N.P. Pavletich et al.. Science 261 1701-1707, 1993.)...
Figure 10.11 Sequence-specific interactions between DNA (yellow) and the recognition helix (red) of the glucocorticoid receptor. Three residues, Lys 461, Val 462 and Arg 466 make specific contacts with the edges of the bases In the major groove. Figure 10.11 Sequence-specific interactions between DNA (yellow) and the recognition helix (red) of the glucocorticoid receptor. Three residues, Lys 461, Val 462 and Arg 466 make specific contacts with the edges of the bases In the major groove.
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See also in sourсe #XX -- [ Pg.119 ]



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Grooves

Grooving

Major groove

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